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Volume 20, Issue 6, Pages (June 2012)

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1 Volume 20, Issue 6, Pages 1051-1061 (June 2012)
Structural Basis for Substrate Targeting and Catalysis by Fungal Polysaccharide Monooxygenases  Xin Li, William T. Beeson, Christopher M. Phillips, Michael A. Marletta, Jamie H.D. Cate  Structure  Volume 20, Issue 6, Pages (June 2012) DOI: /j.str Copyright © 2012 Elsevier Ltd Terms and Conditions

2 Structure 2012 20, 1051-1061DOI: (10.1016/j.str.2012.04.002)
Copyright © 2012 Elsevier Ltd Terms and Conditions

3 Figure 1 Structural Overview of PMO Family Enzymes
(A) A cartoon presentation of N. crassa PMO-2 with the planar surface facing down and the conical tip pointing up. Copper ion is shown as a brown sphere. Disulfides are in yellow. The glycosylated asparagine residue and glycan are shown as sticks with the carbon atoms in magenta and green, respectively. The highly variable loop L2 is colored magenta. (B) PMO-3 from N. crassa viewed as in (A). (C) Structure-based sequence alignment of N. crassa PMOs with other known X-ray crystal structures. Conserved residues are shaded in gray and the residues on the planar surface are colored in light blue. Conserved surface aromatic residues are labeled with pink diamonds. Segments assigned to β strands and α helices are framed with red and cyan lines, respectively, and are labeled in sequential order. Loop L2 is colored magenta. Cysteine residues are highlighted in yellow and linked with black lines to show disulfide bonding. Glycosylated asparagine residues are highlighted in green. Orange asterisks mark the copper-coordinating residues. See also Figure S1. Structure  , DOI: ( /j.str ) Copyright © 2012 Elsevier Ltd Terms and Conditions

4 Figure 2 The Active Site of N. crassa PMOs
(A) A generalized schematic representation of the active site copper coordination. The blue lines denote the substrate binding plane. “R” is most consistent with superoxide in PMO-2 and with hydrogen peroxide in PMO-3 chain A. (B–D) Weighted electron density maps surrounding the active site of PMO-2 chain A (B), PMO-3 chain A (C), and PMO-3 chain B (D) with 2mFO-DFC (in gray, contoured at 1.2 σ). The mFObs-DFCalc difference electron density maps after omitting the whole superoxide or hydrogen peroxide molecule are colored in green; after omitting only the proximal O1 atom are colored in red; and after omitting only the distal O2 atom are colored in blue. The Omit map of 3-hydroxyl group on Tyr24 from PMO-3 chain A is also colored in green and all omit maps are contoured at 3.0 σ. The orientation is approximately equivalent to that shown in the schematic in (A). (E and F) Oxygen-binding grooves in PMO-2 (E) and PMO-3 (F). The positions of bound superoxide and peroxide are shown as red spheres. See also Figure S3. Structure  , DOI: ( /j.str ) Copyright © 2012 Elsevier Ltd Terms and Conditions

5 Figure 3 Conserved Residues across the PMO Family Mapped onto the Structure of N. crassa PMO-3 (A) PMO-3 is shown as cartoon presentation. The protein molecule is related to Figure 1B by rotating about 180 degrees around the vertical axis. The conserved residues with sequence identity higher than 85% are shown as sticks. Most of them can be grouped into four clusters located at the active site (in magenta), the conical tip (in cyan), a patch at the center of the hairpin-shaped C-terminal coil (in yellow), or on the larger sheet of the β sandwich fold (in green). (B) Conserved residues on the surface of PMO-3 that connect to the putative electron transfer pathways are shown on the molecular surface in yellow, mapped onto the structure of N. crassa PMO-3. See also Figure S4. Structure  , DOI: ( /j.str ) Copyright © 2012 Elsevier Ltd Terms and Conditions

6 Figure 4 Models for Substrate Binding by PMOs
(A) Planar surface of PMO-2 showing conserved residues. The globally conserved and the PMO-2 subfamily conserved residues are colored in yellow and green, respectively. The copper ion is shown as an orange sphere. The red arrow indicates the oxygen binding groove. (B) Planar surface of PMO-3 showing conserved residues in PMO-3, as described for PMO-2 in (A), with PMO-3 subfamily residues colored cyan. Dashed lines outline the shallow hydrophilic groove between the H2.1 and the N-glycan in N. crassa PMO-3. (C) Docking of the flat surface aromatic residues of a CBM1 and PMOs to the crystalline cellulose hydrophobic face built from the crystal structure of cellulose Iβ (Nishiyama et al., 2002). Cellulose chains are shown as black lines and the distances between pyranose units are labeled with red dotted lines. Aromatic residues on the flat surface of each protein are shown as sticks and the distances are labeled with blue dotted lines. The carbon atoms of TrCel7A-CBM1 (PDB entry 1CBH), TtGH61E (PDB entry 3EJA), TaGH61A (PDB entry 3ZUD), and NcPMO-3 are colored in yellow, green, magenta, and cyan, respectively. Alternative binding of each protein can be formed by moving along the glucan chain for a distance of an odd number of pyranose units, as shown in the figure for two PMO-3 s, in dark and light cyan, respectively, and separated from each other by three pyranose units along the glucan chain. See also Figure S5. Structure  , DOI: ( /j.str ) Copyright © 2012 Elsevier Ltd Terms and Conditions

7 Figure 5 Active Site and the Substrate Binding Surface in CBM33 Family
(A) Active sites alignment of N. crassa PMO-3 (in cyan) and S. marcescens CBP21 (PDB entry 2BEM, in gray, residue numbers in parentheses). While His1 and His82 are conserved in CBP21, the axial coordinating residue tyrosine, which is absolutely conserved in all PMOs, is replaced with a phenylalanine in many CBM33s. Furthermore, Gln169 and His160 (PMO-3 numbering) are conserved in all PMOs but are not conserved in CBP21. His160 may catalyze the final elimination reaction to cleave the glycosidic bond and is replaced with an aspartic acid in CBP21 and many other CBM33 proteins. (B) Substrate binding surface in the CBM33 family. The S. marcescens CBP21 structure (PDB entry 2BEM) is shown in gray cartoon, with the conserved residues on the flat surface shown as sticks. The conserved hydrophilic residues that have been experimentally proven to be important for chitin binding (Vaaje-Kolstad et al., 2005) are colored in green. In S. coelicolor CelS2, which acts on cellulose (Forsberg et al., 2011), differences in residues arrayed on the planar surface are labeled in parentheses. A sequence insertion in CelS2 that contains four aromatic residues (circles), is modeled schematically in magenta. See also Figure S7. Structure  , DOI: ( /j.str ) Copyright © 2012 Elsevier Ltd Terms and Conditions

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